Duetschler, Alisha; Bauman, Grzegorz; Bieri, Oliver; Cattin, Philippe C; Ehrbar, Stefanie; Engin-Deniz, Georg; Giger, Alina; Josipovic, Mirjana; Jud, Christoph; Krieger, Miriam; Nguyen, Damien; Persson, Gitte F; Salomir, Rares; Weber, Damien C; Lomax, Antony J; Zhang, Ye (2022). Synthetic 4DCT(MRI) lung phantom generation for 4D radiotherapy and image guidance investigations. Medical physics, 49(5), pp. 2890-2903. Wiley 10.1002/mp.15591
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Medical_Physics_-_2022_-_Duetschler_-_Synthetic_4DCT_MRI_lung_phantom_generation_for_4D_radiotherapy_and_image_guidance.pdf - Accepted Version Available under License Publisher holds Copyright. Download (2MB) | Preview |
PURPOSE
Respiratory motion is one of the major challenges in radiotherapy. In this work, a comprehensive and clinically plausible set of 4D numerical phantoms, together with their corresponding 'ground truths', have been developed and validated for 4D radiotherapy applications.
METHODS
The phantoms are based on CTs providing density information and motion from multi-breathing-cycle 4DMRIs. Deformable image registration (DIR) has been utilized to extract motion fields from 4DMRIs and to establish inter-subject correspondence by registering binary lung masks between CT and MRI. The established correspondence is then used to warp the CT according to the 4DMRI motion. The resulting synthetic 4DCTs are called 4DCT(MRI)s. Validation of the 4DCT(MRI) workflow was conducted by directly comparing conventional 4DCTs to derived synthetic 4D images using the motion of the 4DCTs themselves (referred to as 4DCT(CT)s). Digitally reconstructed radiographs (DRRs) as well as 4D pencil beam scanned (PBS) proton dose calculations were used for validation.
RESULTS
Based on the CT image appearance of 13 lung cancer patients and deformable motion of 5 volunteer 4DMRIs, synthetic 4DCT(MRI)s with a total of 871 different breathing cycles have been generated. The 4DCT(MRI)s exhibit an average superior-inferior tumor motion amplitude of 7 ± 5 mm (min: 0.5 mm, max: 22.7 mm). The relative change of the DRR image intensities of the conventional 4DCTs and the corresponding synthetic 4DCT(CT)s inside the body is smaller than 5% for at least 81% of the pixels for all studied cases. Comparison of 4D dose distributions calculated on 4DCTs and the synthetic 4DCT(CT)s using the same motion achieved similar dose distributions with an average 2%/2mm gamma pass rate of 90.8% (min: 77.8%, max: 97.2%).
CONCLUSION
We developed a series of numerical 4D lung phantoms based on real imaging and motion data, which give realistic representations of both anatomy and motion scenarios and the accessible 'ground truth' deformation vector fields of each 4DCT(MRI). The open-source code and motion data allow foreseen users to generate further 4D data by themselves. These numeric 4D phantoms can be used for the development of new 4D treatment strategies, 4D dose calculations, DIR algorithm validations, as well as simulations of motion mitigation and different online image-guidance techniques for both proton and photon radiation therapy. This article is protected by copyright. All rights reserved.
Item Type: |
Journal Article (Original Article) |
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Division/Institute: |
04 Faculty of Medicine > Department of Haematology, Oncology, Infectious Diseases, Laboratory Medicine and Hospital Pharmacy (DOLS) > Clinic of Radiation Oncology |
UniBE Contributor: |
Weber, Damien Charles |
Subjects: |
600 Technology > 610 Medicine & health |
ISSN: |
2473-4209 |
Publisher: |
Wiley |
Language: |
English |
Submitter: |
Pubmed Import |
Date Deposited: |
07 Mar 2022 09:32 |
Last Modified: |
05 Mar 2023 00:25 |
Publisher DOI: |
10.1002/mp.15591 |
PubMed ID: |
35239984 |
BORIS DOI: |
10.48350/166571 |
URI: |
https://boris.unibe.ch/id/eprint/166571 |